Chiral compounds aldols

Transfer of chirality in aldol reactions has been attempted using / -allenyl ester enolates. These ambident nucleophiles have an axis of chirality, and such compounds have been less utilized in stereoselective reactions. They are prepared by transmetallation of the... 

The Evans Cu(II)- and Sn(II)-catalyzed processes are unique in their ability to mediate aldol additions to pyruvate. Thus, the process provides convenient access to tertiary a-hydroxy esters, a class of chiral compounds not otherwise readily accessed with known methods in asymmetric catalysis. The process has been extended further to include a-dike-tone 101 (Eqs. 8B2.22 and 8B2.23). It is remarkable that the Cu(II) and Sn(II) complexes display enzyme-like group selectivity, as the complexes can differentiate between ethyl and methyl groups in the addition of thiopropionate-derived Z-silyl ketene acetal to 101. As discussed above, either syn or anti diastereomers may be prepared by selection of the Cu(II) or Sn(II) catalyst, respectively. 

Although carbohydrates are cheap and readily available chiral compounds, their application in stereoselective synthesis was for a long time limited to ex-chiral-pool syntheses [3]. They have been considered too complex compared to other chiral auxiliaries, for example a-pinene in borane-chemistry [4] or BINAP-derivatives in reduction chemistry [5]. However, it has been shown during the past few years that carbohydrates can be successfully applied as stereodifferentiating tools in many different reaction types such as aldol- [6], hydrogenation- [7], carbonyl addition- [8], Michael- [9], Diels-Alder- [10], hetero-Diels-Alder [11], and rearrangement reactions [12]. 

Aldol reactions are ubiquitous in synthetic organic chemistry to generate intermediates of antihypertensive dmgs and calcium antagonists. Chiral p-hydroxy carbonyl compounds can readily be converted to 1, i-syn and anfr-diols and amino alcohols, which are the building blocks in many natural products such as antibiotics and pheromones and in many biologically active compounds. Aldol products have successfully been converted to key synthetic intermediates of epithilone A and bryostatin 7. ... 

Although asymmetric organocatalysis is now considered as a powerful tool for the synthesis of chiral compounds this research held experimented its own revolution. It was restricted after the seventies only to the nse of simple a-amino acids as catalyst for the Robinson annulations and above all with the application of proline to the enantioselective intermolecular aldol reaction. 

Carbohydrates are inexpensive chiral compounds. In one molecular unit they contain numerous chiral informations. Despite of these striking properties, carbohydrates have been applied only in isolated cases as chiral auxiliaries in stereoselective syntheses. First, asymmetric reductions were studied with carbohydrate-modified reducing reagents. More recently, aldol reactions and Diels-Alder reactions with carbohydrate-linked substrates have been described. 

BF4] or [bmim][PF6] (Scheme 22.8). Bis-amide 19-catalyzed aldol reactions performed in [bmimllBFJ required a much lower excess of donor ketone 21 (3 equiv. instead of 30 equiv. in proline-catalyzed reactions) and allowed a synthesis of chiral compounds 22 bearing heterocyclic, prenyl, or metallocene units [43], The improved catalytic performance of prolinamide derivatives in ionic liquids might be due to a stabihzation of the iminium intermediate formed from the ketone and the catalyst or because of the enhanced nucleophilicity of the enamine [42]. Notably, IL dilution with water (1 1 by volume) accelerated the enamine/iminium ion hydrolysis and raised reaction rates and product yields, with the enantioselec-tivity being retained or even becoming somewhat higher than under water-free conditions [45], Furthermore, the catalyst/lL/water system could be easily recycled five times without aldol yield, dr, and ee losses. 

Asymmetric catalysis is an important technique for the synthesis of chiral compounds. The introduction of supported IL catalyst into the field of asymmetric catalysis might offer new approaches to improve the catalytic performance and also the reusabiUty of chiral catalysts. The first example of a supported IL asymmetric catalyst is the proUne-catalyzed aldol reaction [116]. In this work, the IL molecule covalently attached to modified silica gel was used as the support for IL-phase containing L-proUne. The modification of the silica gel surface by the IL molecule is crucial to gain high enantioselectivity. In the model reaction of acetone and benzaldehyde, the yield to 4-hydroxy-4-phenylbutan-2-one was 51% with 64% ee. Otherwise, the yield was only 38% with 12% ee without the silica gel modification. 

Chiral salen chromium and cobalt complexes have been shown by Jacobsen et al. to catalyze an enantioselective cycloaddition reaction of carbonyl compounds with dienes [22]. The cycloaddition reaction of different aldehydes 1 containing aromatic, aliphatic, and conjugated substituents with Danishefsky s diene 2a catalyzed by the chiral salen-chromium(III) complexes 14a,b proceeds in up to 98% yield and with moderate to high ee (Scheme 4.14). It was found that the presence of oven-dried powdered 4 A molecular sieves led to increased yield and enantioselectivity. The lowest ee (62% ee, catalyst 14b) was obtained for hexanal and the highest (93% ee, catalyst 14a) was obtained for cyclohexyl aldehyde. The mechanism of the cycloaddition reaction was investigated in terms of a traditional cycloaddition, or formation of the cycloaddition product via a Mukaiyama aldol-reaction path. In the presence of the chiral salen-chromium(III) catalyst system NMR spectroscopy of the crude reaction mixture of the reaction of benzaldehyde with Danishefsky s diene revealed the exclusive presence of the cycloaddition-pathway product. The Mukaiyama aldol condensation product was prepared independently and subjected to the conditions of the chiral salen-chromium(III)-catalyzed reactions. No detectable cycloaddition product could be observed. These results point towards a [2-i-4]-cydoaddition mechanism. 

The major developments of catalytic enantioselective cycloaddition reactions of carbonyl compounds with conjugated dienes have been presented. A variety of chiral catalysts is available for the different types of carbonyl compound. For unactivated aldehydes chiral catalysts such as BINOL-aluminum(III), BINOL-tita-nium(IV), acyloxylborane(III), and tridentate Schiff base chromium(III) complexes can catalyze highly diastereo- and enantioselective cycloaddition reactions. The mechanism of these reactions can be a stepwise pathway via a Mukaiyama aldol intermediate or a concerted mechanism. For a-dicarbonyl compounds, which can coordinate to the chiral catalyst in a bidentate fashion, the chiral BOX-copper(II)... 

The Hantsch pyridine synthesis provides the final step in the preparation of all dihydrop-yridines. This reaction consists in essence in the condensation of an aromatic aldehyde with an excess of an acetoacetate ester and ammonia. Tlie need to produce unsymmetrically subsrituted dihydropyridines led to the development of modifications on the synthesis. (The chirality in unsymmetrical compounds leads to marked enhancement in potency.) Methyl acetoacetate foniis an aldol product (30) with aldehyde 29 conjugate addition of ethyl acetoacetate would complete assembly of the carbon skeleton. Ammonia would provide the heterocyclic atom. Thus, application of this modified reaction affords the mixed diester felodipine 31 [8]. 

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